The Gaussian surface for calculating the electric field due to a charge distribution is

Calculate electric field due to a charge uniformly distributed in a spherical volume

It is not convenient to use a spherical Gaussian surface to find the electric field due to an electric dipole using Gauss's theorem because:

Electric Field due to Dipole

The law goverening electrostatics is coulomb's law.In priciple coulomb's law can be used to compute electric field due to any charge configuation .In pracitce however it is a formidable task to compute electric field due to uniform charge distributions .For such cases Gauss proposed a theorem which states that ointbar(E).bar(ds)=(q)/(epsilon_(0)) where ds is an element of area directed across the outward normal for the surface at every point .The integral is called electric flux.Any convenient surface that we choose to evalute the surface integral is called the Gaussian surface. The SI unit of electric flux is

A insulating cylindrical rod of diameter d and length l(l gt gt d) has a uniform surface charge density such that the electric field just outside the curved surface of the cylinder at point M is E_(0) . Find the electric field due to charge distribuition at point P (r gt gt l) .

A charge Q is placed at the centre of an inaginary hemispherical surface. Using symmetry arguments and the Gauss's law, find the flux of the electric field due to this charge through the surface of the hemisphere (figure ).

Figure shows a conducting sphere with a cavity. A point charge q_(1) is placed inside cavity, and q_(2) is placed out side the sphere vec(E)_("in") is electric field due to charge induced on surface of cavity. vec(E)_("out") is electric field due to charge induced on outer surface of sphere and vec(E)_("net") is net field at any point. Two closed gaussian surface S_(1) & S_(2) are also drawn in the figure.

The spatial distribution of the electric field due to charges (A,B) is shown in figure. Which of the following statements is correct?

A charge 'Q' is placed at the centre of a hemispherical surface of radius 'R'. The flux of electric field due to charge 'Q' through the surface of hemisphere is

A charge is moved in an electric field of a fixed charge distribution from point A to another point B slowly. The work done by external agent in doing so is 100 J . What is the change in potential energy of the charge as it moves from A to B ? What is the work done by the electric field of the charge distribution as the charge moves from A to B ?